DE2836526A1 - DRYING DEVICE OPERATING WITH SOLAR ENERGY, IN PARTICULAR FOR DRYING AGRICULTURAL PRODUCTS - Google Patents

Description

.. .. r- :. Il Weickmann, Dipl. Phys. Dr. K. Findce

Tue ..;. i "j. r. Λ. V / eickinann, Dipl. Chem. D. Huber 2 1. Λμλ. «Ητο

Wa Df.-Ing. H. Liska ... °

Möhlstre'je 22, 8000 Munich 85

FIAT Society per Azioni
Corso Marconi 10
Turin, Italy

Drying device that can be operated with solar energy, in particular for drying agricultural products.

The invention relates to a device that can be operated with solar energy, by means of which, in particular, agricultural devices Moisture can be removed from products, e.g. grain, whereby these are dried in such a way that they stand out better suitable for further use.

It is known to bring agricultural products into containers for drying and to dry them there with hot air.

The invention is based on the object of achieving the same purpose without the expense of expensive external energy. This object is achieved by a drying device which can be operated with solar energy and which is characterized by a solar collector for heating a drying medium, which is connected to a container for the products to be dried is.

The invention is explained in more detail below with reference to the drawings:

Fig. 1 shows a sectional view of the drying device according to the invention,

Fig. 2 shows a partial section through the drying device along the line H-II of Fig. 1 and represents the

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The area in which the products are brought to dry.

The drying device 2 shown in Fig. 1 essentially comprises a solar collector 4 and a container 6.Die Drying device 2 is carried by a framework S, which has feet provided with rollers 9 and with these on rests on the ground so that the drying device can be easily moved and positioned.

The solar collector 4 absorbs heat from solar radiation and consequently supplies hot air into the container The solar collector 4 has a surface which is exposed to solar radiation and which is around such a surface relative to the vertical Angle is inclined so that a maximum amount of solar energy falls on the collector.

The solar collector 4 comprises a pane of glass 10. This forms that wall of the collector that of the solar energy source is facing. Further components of the solar collector 4 are an insulating layer 14, a heat-absorbing one Plate 11 which carries a number of vessels 12 which are provided with a selective black lacquer coating and thus facilitate and enlarge the absorption of solar energy and prevent heat loss to the outside.

The solar collector 4 is surrounded and enclosed by a cover 13, which extends over all of the outer surfaces Except for the glass plate 10 extends. This cover 13 can be made of metal, plastic material or the like be.

On the lower wall of the cover 13, a line 16 facing the floor is attached, via which the solar collector atmospheric air can be supplied.

At the lower edge adjoining the glass plate 10

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Cover 13 is hinged to a reflective plate 18 relative to the surface exposed to solar radiation of the solar collector 4 can assume different angular positions, so that the reflective Plate 18 falling solar radiation is deflected to the collector and thus increased its performance.

The reflective plate 18 can also be pivoted completely over the surface of the solar collector 4 which is exposed to the sun so that this surface is protected when the drying device is not in operation.

As can be seen from Fig. 1, the container 6 is essentially cuboid. To avoid heat loss, its walls are designed to be insulating. In his In the bottom area there is a conveyor 20, its upper end is provided with a cover 21.

One or more walls of the container 6 can be opened to the front so that drawers 22 are inserted or removed containing the agricultural products to be dried and arranged within the container are.

The surfaces of the drawers 22 are air-permeable and consist of a network of metal, plastic or the like Material.

The drawers 22 have the same dimensions with the exception of their length. They are inside the container through (not shown) known means attached.

As can be seen from Fig. 2, the drawers 22 are offset within the container 6, so that the of the Solar collector 4 coming heated air covers a corresponding winding path, whereby the heat exchange between the heated air and the

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products is improved.

A wall of the container 6, namely the wall adjacent to the sun-exposed surface of the solar collector 4, can be designed as a reflective plate, so that the amount of solar radiation falling on the solar collector 4 is enlarged.

As can be seen from Fig. 1, the top of the cover ends 20 in a line piece 24 which serves as an air outlet. A cylindrical pipe connection with an elbow 26 is rotatably connected to the line piece 24. A wind vane 28 is provided on its upper side.

This wind vane 28 causes that the outlet of the connector 26 is moved in the direction of the wind, whereby the exit and flow of warm air within the drying device is facilitated.

The upper end of the solar collector 4 is with that area of the container 6 in which the conveyor 20 is located, so that the heated air from the solar collector enters the container 6 directly.

At the bottom of the container 6 is a grid above the conveyor 26 30 arranged. The openings in this grid are of different sizes. The smaller openings are on the side arranged at which the air outlet of the solar collector 4 is located. Normally, the air entering the container 6 from the collector 4 via the conveyor 20 tries in the outlet area of the collector 4 to rise vertically upwards, through the effect of the grating 30, however, it is evenly distributed over the entire base area of the grating 30 and can as a result flow uniformly through the entire cross-sectional area of the container 6.

In the part of the container 6 in which the conveyor 20

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is located, a thermostatic piston 31 is attached. It very soon reaches the same temperature as that in the Container 6 entering air. The thermostatic flask 31 contains a liquid such as Freon 11 or the like, which has a low evaporation point. When the temperature in the container 6 increases, it increases the pressure of the liquid in the thermostatic flask 31.

Two lines 32 and 34 extend from the piston 31. the Line 32 connects the piston 31 with a pressure cell 36, which is opposite the opening through which the air enters the solar collector 4 from the line 16. The administration 34 connects the thermostatic piston 31 to a pressure cell 38, which is opposite the opening through which the air reaches the line piece 24 from the container 6.

A rod 40 connects the pressure cell 36 with a movable partition 42 which is pivotable about the axis 41 in the line piece 1-6 is stored.

A counter spring 44 is mounted in the line piece 16 The end of this spring 44 is connected to the partition wall 42, while the other end is connected to the interior of the line piece attached 1st.

A rod 46 connects the pressure cell 48 with a movable partition 48 which is pivotable about the axis 49 within of the LeltungsStückes 24 is stored. A return spring 50 is mounted inside the line piece 24. An end this counter spring 50 is connected to the partition wall 48, while its other end is inside the line piece 24 attached 1st.

The connections between the thermostatic piston 31 made by the means described above and the partitions 42 and 48 are calibrated so that

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the partition wall 48 in the line piece 24 only begins to close when, after the in the line section 16 arranged partition 42 has passed a certain time.

Through this time difference when closing the partition walls 42 and 48, the following is achieved: When the on the solar collector 4 incident solar energy decreases and accordingly in the conveyor 20 and the thermostatic Piston 31 containing area of the container 6 entering air has a lower temperature, the temperature remains Partition wall 40 is still in its open position for a long enough time so that the one in the container is hot Air escape through the line piece 24 and the connection 26 can, so that the moisture they previously in the container 6 agricultural products has withdrawn, is discharged.

The counter springs 44 and 50 ensure that the movable partitions connected to them at the air inlet and outlet of the drying device remain closed, so that their operation is automatically stopped when the The sunlight is too weak to warm the air to the temperature required to dry the products.

The mode of action is as follows:

If there is no exposure to sunlight, no air escapes through the line piece 16, since the partition wall 42 is held closed by the spring 44.

In this case, no air can escape into the atmosphere through the line piece 24 and the connection 26, since the partition wall 48 is kept closed by the spring 50.

Nevertheless, there is a certain amount of air inside the

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Drying device 2.

As soon as the solar radiation is sufficiently strong, the air present in the drying device 2 is heated noticeably. This leads to an increase in the temperature of the thermostatic piston 31, so that the pressure in it contained liquid increases. This pressure rise is via lines 32 and 34 to those connected to them Transferring pressure cans 36 and 38, respectively.

As a result of the prevailing pressure, the pressure cell 36 pushes the Rod 40 against the resistance of the spring 44 downwards and thus pivots the partition wall 42, so that the solar collector 4 is connected to the atmosphere via the line piece 16.

At the same time the temperature inside the solar collector rises 4 due to the heat absorbing plate absorbed solar radiation compared to the outside temperature. As a result, it can be in the immediate vicinity of the line section 16 existing air through this line piece 16 and the partially open partition wall 42 into the solar collector 4 and is sucked in by natural convection.

During its passage through the interior of the solar collector 4, the air is due to the heat exchange through the contact with the heat absorbing plate 11 is heated. The effect of this heat exchange is due to the the special arrangement of the cans 12 on the heat absorbing plate 11 reinforces the forced winding path of the air. The air heated in this way flows into the area of the container 6 in which the conveyor 20 is located.

The heated air then travels through the openings in the grille 30 and passes through the drawers 22 that hold the contain product to be dried. Own the drawers 22

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- as mentioned - a net-like construction and thus absorb the heat of the air. This adds moisture to the product withdrawn so that it is partially dried.

Due to the offset arrangement of the drawers 22, the air moves in this area along a winding path, whereby the heat exchange with the one in the drawers 22 Product is enlarged.

By increasing the pressure in the thermostatic piston 31 located liquid moves the pressure cell 28 the rod 46 against the resistance of the spring 50 down and pivoted the partition 48, so that the container 6 is connected to the atmosphere via the line piece 24 and the connection 26.

By pivoting the partition wall 46, the hot air escapes from the container 6 via the line piece 24 and the compound 26 into the atmosphere.

If more hot air from the solar collector 4 reaches the area of the container 6 in which the conveyor 20 and the thermostatic piston 31 are located, the temperature is this further air higher than that of the air already in this area. This leads to a further increase in pressure of the liquid in the thermostatic piston 31. This further increase in pressure causes the pressure cells 36 and 36 to expand 38 even further.

As a result, the pressure cell 36 moves the rod 40 further downward and thus pivots the partition wall 42 about one larger angle than in the previous phase, so that a larger opening for the line piece 16 to the solar collector 4 flowing air is created. For the same reason, the pressure cell 38 moves the rod 46 further down, see above that the partition wall 48 is pivoted through a greater angle than during the previous phase and a

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larger outlet opening for the from the container 6 via the line piece 24 and the connection 26 to the atmosphere released air is formed.

Since a larger amount of air is now promoted through the solar collector 4, the drying effect for the product located in the drawers 22. This process repeats itself in a similar way over and over again until the two Partition walls are fully open when the two pressure cells have reached their greatest possible extent.

When the heat generated by the solar radiation decreases, the air traveling through the solar collector 4 decreases less heat and has when it enters the area of the container 6 in which the thermostatic piston 31 "is a lower temperature than the previous one Phase. As a result, the pressure of the liquid in the thermostatic piston 31 decreases, so that the pressure cans 36 and 38 pull together. This pulls the Pressure cell 36- the rod 40 back, which now pivots the partition wall 42 in the opposite direction, so that the through the line piece 16 leading connection between the atmosphere and the solar collector 4 is reduced. From the same The reason why the pressure cell 38 pulls the rod 46 back, as a result of which the partition wall 48 also swivels in the opposite direction and the communication between the container 6 via the line piece 24 and the connection 26 and the atmosphere is partially interrupted.

This process continues in a similar manner until the solar radiation allows for efficient operation of the drying ST device 2 has become too weak.

As the temperature continues to drop, the liquid will be drawn in in the thermostatic piston 31 together, so that the pressure cells 36 and 38 contract further. the Pressurized cell 36 pulls the rod 40 back further so that the

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Partition wall 42 is pivoted further in the closing direction, until the connection between the atmosphere and the solar collector 4 is completely interrupted. Then pulls the pressure cell 38 the rod 46 back, whereby the partition wall 48 is pivoted further in the closing direction until the connection between the container 6 and the atmosphere is finally completely interrupted.

The partition wall 40 is completely closed before the heated air has completely escaped into the atmosphere, after removing moisture from the product stored in the drawers.

The springs 44 connected to the partition walls 42 and 48 and 50 keep them in their closed position when the drying device is not in operation or when the sun is shining not sufficient for normal operation.

The system described above can completely dry the agricultural products in question, without the need for complicated and expensive systems.

The preceding description has referred to a drying system that uses air that is more heated than this normally attainable with a stream of air by natural convection.

If necessary, for example opposite the line pieces 16 or 22, a fan can be attached.

To ensure that the fan only works when it is used to increase the air flow inside the drying device is required, a suitably calibrated sensor element that is connected to the thermostatic Piston is connected to be inserted into the electrical connection between the fan and the power source.

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Then, when the thermostatic piston detects a high temperature in the container, it actuates the sensor element, which in turn turns on the fan by connecting it to the electrical power source. If vice versa the thermostatic flask has a low temperature or a temperature in which for drying the agricultural Product in the container determines optimal temperature range, he actuates the sensor in the opposite direction and thus disconnects the fan from the power supply so that it comes to a standstill.

To ensure the autonomy of the drying device, the fan is preferably by optoelectronic Converter elements, e.g. solar cells, are fed and their energy output is advantageously stored in accumulators that serve as buffers is cached.

The invention is of course not restricted to the exemplary embodiment described above. Its construction details can rather be modified in numerous ways familiar to the relevant expert, without departing from the principle on which the invention is based.

in particular, the described embodiment of the solar collector be replaced by other types of solar collectors suitable for heating air.

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Claims (21)

2836520 claims 1. Drying device that can be operated with solar energy, in particular for drying agricultural products, characterized by a solar collector (4) for heating a drying medium (e.g. air), which is provided with a container (6) for the products to be dried connected is. 2. Drying device according to claim 1, characterized in that in the container (6) in the region of the outlet opening the solar collector (4) a thermostatic piston (31) is arranged. 3. Drying device according to claim 2, characterized in that two of the thermostatic piston (31) Lines (32, 34) go out, the first of which connects the piston (31) with a first in the area of the solar collector (4) leading air inlet duct (16) arranged expandable element (36) connects, while the other connects the piston (31) with a second expandable element (38) opposite the air outlet duct leading away from the container (6) (24, 26) is arranged. 4. Drying device according to claim 3 »characterized in that that the expandable elements (36, 38) each via a rod (40 or 46) with a movable Partition wall (42, 48) are connected. 5. Drying device according to claim 4, characterized in that that one of the movable partition walls (42) within the air inlet line leading into the solar collector (4) (16) and the other (48) arranged within the air outlet line (24, 26) leading away from the container (6) are. 6. Drying device according to claim 5 or 5, d a - 909812/0716 characterized in that the movable partitions (42, 48) are pivotable about an axis of rotation within the relevant lines (16 or 24, 26). 7. Trοcknungsvorrichtung according to claim 4 or 5, d a through characterized in that each of the movable partition walls (42, 48) is provided with one end of a spring (44 or 50) is connected, the other end in the Innenraixm of the line piece (16 or 24) containing the relevant partition (42 or 48) is attached. 8. drying device according to claim 1, characterized by, that the solar collector (4) is arranged inclined relative to the vertical. 9. Drying device according to claim 1, characterized in that that with the lower edge of the cover (13) of the solar collector (4) a reflective plate (18) is articulated, which can be pivoted completely over the effective surface of the solar collector (4) is. - 10. Drying device according to claim 1, characterized in that that the walls of the container (6) are designed to be insulating. 11. Drying device according to claim 10, characterized in that that one or more of the turns of the container (6) are to be opened at the front. 12. Drying device according to claim 10, characterized in that that that wall of the container (6) which is exposed to the sun's surface Solar collector (4) is adjacent, is provided with an outwardly reflective plate. 13. Drying device according to claim 1, characterized in that 909812/0716 indicates that air-permeable, removable drawers (22) are arranged in the container (6). 14. Drying device according to claim 13 »characterized in that that the drawers (22) have surfaces designed as a mesh network. 15. Drying device according to claim 13? characterized, that the drawers (22) have the same dimensions with the exception of their width. 16. Drying device according to claim 13, characterized in that that the drawers (22) are arranged offset within the container (6). 17. Drying device according to claim 1 and 13 »d a through characterized in that a grid (30) is attached within the container (6) under the drawers (22). 18. Drying device according to claim 17, characterized in that that the openings of the grid (30) have different sizes. 19. Drying device according to claim 1 and ^, characterized in that the grid (30) in the container (6) is arranged so that the smaller openings are in the vicinity of the area which connects the solar collector (4) with the container (6). 20. Drying device according to claim 1, characterized in that that in the air outlet line (24, 26) leading away from the container (6) a freely rotatable cylindrical Connection is inserted. 21. Drying device according to claim 20, characterized in that that the cylindrical "connection comprises a wind vane (28). 909812/0716